scRNAseqApp Guide

Jianhong Ou

1 Introduction

Single-cell RNA sequencing (scRNA-seq) is a powerful technique to study gene expression, cellular heterogeneity, and cell states within samples in single-cell level. The development of scRNA-seq shed light to address the knowledge gap about the cell types, cell interactions, and key genes involved in biological process and their dynamics.

To increase the re-usability and reproducibility of scientific findings, more and more publishers require raw data and detailed descriptions of how the data were analyzed. However, difficulties arise due to the highly concise descriptions of analysis and the differences of the computing environments. Furthermore, to precisely meet the publishing requirement, the communication of the bioinformatician with researchers is a time-consuming step. Multiple interactive visualization tools were developed to provide the researchers access to the details of the data. Those tools include, but not limited to, alona¹, ASAP², Asc-Seurat³, BingleSeq⁴, CellView⁵, cellxgene VIP⁶, Cerebro⁷, CHARTS⁸, ChromSCape⁹, Cirrocumulus¹⁰, CReSCENT¹¹, Cytosplore Viewer¹², Granatum¹³, InterCellar¹⁴, iS-CellR¹⁵, iSEE¹⁶, loom-viewer, Loupe Cell Browser, PIVOT¹⁷, SC1¹⁸, SCANNER¹⁹, scClustViz²⁰, SCope²¹, scSVA²², scVI²³, SeuratV3Wizard²⁴/NASQAR, ShinyArchRUiO²⁵, ShinyCell²⁶, singleCellTK²⁷, Single Cell Explorer (scExplorer)²⁸, Single Cell Interactive Application (SCiAp)²⁹ and UCSC Cell Browser³⁰, SPRING³¹, WASP³², and Vitessce³³.

The basic information of the tools are list in the following tables (the table was created at 12/06/2022):

Tool	platform	plot type
alona	web-based	scatters, bar
ASAP	web-based	scatters
Asc-Seurat	shiny package	scatters, heatmap, violin, dot, trajectory
BingleSeq	shiny package	scatters, heatmap, violin, ridge
CellView	shiny package	scatters
cellxgene VIP	web-based	scatters, bar, and visualization plugin
Cerebro/cerebroApp	shiny package	scatters, 3D scatters
CHARTS	web-based	scatters, bar
ChromSCape	shiny package	scatters, heatmap
Cirrocumulus	python package
CReSCENT	web-based	scatters, violin
Cytosplore Viewer	Cytosplore	scatters, phylogeny
Granatum	shiny package	scatters, bar, trajectory, ppi
InterCellar	shiny package	dot, ppi, circos, radar, pie
iS-CellR	shiny package	scatters, heatmap, violin, bar, dot
iSEE	shiny package	scatters, heatmap, violin, bar
loom-viewer	python package
Loupe Cell Browser	Desktop	scatters
PIVOT	shiny package	scatters, heatmap, violin, bar, pie
SC1	web-based	scatters, heatmap, violin, bar
SCANNER	web-based	scatters
scClustViz	shiny package	scatters, heatmap, violin, bar, dot
scExplorer	web-based	scatters, heatmap
SCope	web-based	scatters
scSVA	shiny package	scatters, 3D scatters
scVI	python package	scatters, heatmap, violin, bar
seuratv3wizard	web-based	scatters
ShinyArchRUiO	shiny package	scatters, heatmap, track
ShinyCell	shiny package	scatters, heatmap, violin, bar
SCiAp111 short name for Single Cell Interactive Application	galaxy
singleCellTK	shiny package	scatters, heatmap, violin, dot, trajectory
SPRING	python package	scatters
UCSC Cell Browser	web-based	scatters
Vitessce	python package	scatters, heatmap
WASP	shiny package	scatters, heatmap

Tool	languages	license	starts	watching	forks	citation
alona	python	GPL-3	12	3	5	24
ASAP	Java,R,Python	GPL-3	18	6	8	88
Asc-Seurat	R	GPL-3	12	2	6	10
BingleSeq	R	MIT	18	2	6	4
CellView	R	MIT	16	9	8	8
cellxgene VIP	python,R,JavaScript	MIT	81	6	24	10
Cerebro/cerebroApp	R,JavaScript,C	MIT	79	7	18	41
CHARTS	python	MIT	2	6	0	7
ChromSCape	R	GPL-3	11	2	4	13
Cirrocumulus	JavaScript,Python	BSD-3	38	7	9	78
CReSCENT	R,Perl	GPL-3	8	1	4	11
Cytosplore Viewer	java,javascript
Granatum	R	Apache2	18	4	11	65
InterCellar	R	MIT	7	1	3	4
iS-CellR	R	GPL-3	21	6	6	15
iSEE	R	MIT	201	14	39	41
loom-viewer	python,JavaScript	BSD-2	32	9	6
Loupe Cell Browser
PIVOT	R		27	6	15	27
SC1	R					5
SCANNER	R		0	2	1	1
scClustViz	R	MIT	41	12	10	36
scExplorer	JavaScript,Python	GPL-3	7	3	6	16
SCope	python,JavaScript	GPL-3	60	8	14	438222 the package contribute paritial to the citation
scSVA	R	GPL-3	20	6	7	8
scVI	python	BSD-3	840	27	263	787
seuratv3wizard	R	GPL-3	29	8	13	28333 citation is from NASQAR
ShinyArchRUiO	R	GPL-3	11	2	4	3
ShinyCell	R	GPL-3	70	9	23	28
SCiAp						16
singleCellTK	R	MIT	105	12	61	6
SPRING	python,matlab,JavaScript		59	10	29	250
UCSC Cell Browser	JavaScript,Python,R	GPL-3	3	1	39	46
Vitessce	JavaScript,Python,R	MIT	92	6	23	2
WASP	R,python		2	1	0	3

Tool	source code
alona	https://github.com/oscar-franzen/adobo/
ASAP	https://github.com/DeplanckeLab/ASAP
Asc-Seurat	https://github.com/KirstLab/asc_seurat/
BingleSeq	https://github.com/dbdimitrov/BingleSeq/
CellView	https://github.com/mohanbolisetty/CellView
cellxgene VIP	https://github.com/interactivereport/cellxgene_VIP
Cerebro/cerebroApp	https://github.com/romanhaa/Cerebro
CHARTS	https://github.com/stewart-lab/CHARTS
ChromSCape	https://github.com/vallotlab/ChromSCape
Cirrocumulus	https://github.com/lilab-bcb/cirrocumulus
CReSCENT	https://github.com/pughlab/crescent
Cytosplore Viewer
Granatum	https://github.com/lanagarmire/Granatum
InterCellar	https://github.com/martaint/InterCellar
iS-CellR	https://github.com/immcore/iS-CellR
iSEE	https://github.com/iSEE/iSEE
loom-viewer	https://github.com/linnarsson-lab/loom-viewer
Loupe Cell Browser
PIVOT	https://github.com/kimpenn/PIVOT
SC1
SCANNER	https://github.com/GuoshuaiCai/scanner
scClustViz	https://github.com/BaderLab/scClustViz
scExplorer	https://github.com/d-feng/scExplorer
SCope	https://github.com/aertslab/Scope
scSVA	https://github.com/klarman-cell-observatory/scSVA
scVI	https://github.com/scverse/scvi-tools
seuratv3wizard	https://github.com/nasqar/seuratv3wizard
ShinyArchRUiO	https://github.com/EskelandLab/ShinyArchRUiO
ShinyCell	https://github.com/SGDDNB/ShinyCell
SCiAp
singleCellTK	https://github.com/compbiomed/singleCellTK
SPRING	https://github.com/AllonKleinLab/SPRING_dev
UCSC Cell Browser	https://github.com/ucscGenomeBrowser/cellBrowser
Vitessce	https://github.com/vitessce/vitessce
WASP	https://github.com/andreashoek/wasp

Tool	demo
alona	https://alona.panglaodb.se/
ASAP	https://asap.epfl.ch/
Asc-Seurat
BingleSeq
CellView	https://mbolisetty.shinyapps.io/CellView/
cellxgene VIP	https://cellxgenevip-ms.bxgenomics.com/
Cerebro/cerebroApp
CHARTS	https://charts.morgridge.org/
ChromSCape	https://vallotlab.shinyapps.io/ChromSCape/
Cirrocumulus
CReSCENT	https://crescent.cloud/
Cytosplore Viewer
Granatum	http://granatum.dcmb.med.umich.edu:8103/
InterCellar
iS-CellR
iSEE	https://marionilab.cruk.cam.ac.uk/iSEE_allen/
loom-viewer
Loupe Cell Browser
PIVOT
SC1	https://sc1.engr.uconn.edu/
SCANNER	https://www.thecailab.com/scanner/
scClustViz	https://innesbt.shinyapps.io/scclustvizdemoapp/
scExplorer	http://singlecellexplorer.org
SCope	https://scope.aertslab.org/
scSVA
scVI
seuratv3wizard	https://nasqar.abudhabi.nyu.edu/SeuratV3Wizard/
ShinyArchRUiO	https://cancell.medisin.uio.no/ShinyArchR.UiO/
ShinyCell	http://shinycell1.ddnetbio.com/
SCiAp	https://humancellatlas.usegalaxy.eu/
singleCellTK	https://sctk.bu.edu/
SPRING.	https://kleintools.hms.harvard.edu/tools/
	springViewer_1_6_dev.html?datasets/mouse_HPCs/
	basal_bone_marrow/full444 URL shown in multiple lines
UCSC Cell Browser	https://cells.ucsc.edu/
Vitessce	http://vitessce.io/
WASP

Tool	visualization tutorial
alona	https://alona.panglaodb.se/faq.html
ASAP	https://asap.epfl.ch/home/tutorial?t=fca
Asc-Seurat	https://asc-seurat.readthedocs.io/en/latest/index.html
BingleSeq	https://github.com/dbdimitrov/BingleSeq/blob/master/README.md
CellView
cellxgene VIP	https://interactivereport.github.io/cellxgene_VIP/tutorial/docs
Cerebro/cerebroApp	https://romanhaa.github.io/cerebroApp/
CHARTS	https://github.com/stewart-lab/CHARTS/blob/master/README.md
ChromSCape	https://vallotlab.github.io/ChromSCape/articles/vignette.html
Cirrocumulus	https://cirrocumulus.readthedocs.io/en/latest/
CReSCENT	https://pughlab.github.io/crescent-frontend/
Cytosplore Viewer	https://viewer.cytosplore.org/
Granatum	https://github.com/lanagarmire/Granatum/blob/master/doc/
	Granatum_manual_0.92.pdf555 URL shown in multiple lines
InterCellar
iS-CellR
iSEE
loom-viewer	https://github.com/linnarsson-lab/loom-viewer
Loupe Cell Browser
PIVOT	https://rawgit.com/qinzhu/PIVOT/master/inst/app/www/manual_file.html
SC1
SCANNER
scClustViz
scExplorer	http://singlecellexplorer.org/tutorial.html
SCope	https://github.com/aertslab/SCope/blob/master/README.md
scSVA	https://github.com/klarman-cell-observatory/scSVA/blob/
	master/docs/index.md666 URL shown in multiple lines
scVI	https://docs.scvi-tools.org/en/stable/user_guide/index.html
seuratv3wizard	https://github.com/nasqar/seuratv3wizard/blob/master/README.md
ShinyArchRUiO
ShinyCell	https://github.com/SGDDNB/ShinyCell/blob/master/README.md
SCiAp
singleCellTK
SPRING	https://kleintools.hms.harvard.edu/tools/spring.html
UCSC Cell Browser	https://cellbrowser.readthedocs.io/en/master/interface.html
Vitessce	http://vitessce.io/docs/
WASP	https://github.com/andreashoek/wasp/blob/main/README.md

2 Motivation

Based on ShinyCell, The scRNAseqApp package is developed with multiple highly interactive visualizations of how cells and subsets of cells cluster behavior. The end users can discover the expression of genes in multiple interactive manners with highly customized filter conditions by selecting metadata supplied with the publications and download the ready-to-use results for republishing.

3 Quick start

Here is an example using scRNAseqApp with a subset of scRNA-seq data.

3.1 Installation

First, install scRNAseqApp and other packages required to run the examples. Please note that the example dataset used here is from a small subset of PBMC³⁴. Additional package are also required for enhancement functions such trajectory analysis or cell communication analysis.

library(BiocManager)
BiocManager::install("scRNAseqApp")

3.2 Load library

library(scRNAseqApp)

3.3 Initial the database

publish_folder=tempdir()
scInit(app_path=publish_folder)

3.4 Start shiny app

scRNAseqApp(app_path = publish_folder)

4 Create a new data

There are two ways to create a new data.

• from the administrator mode
• use R session

4.1 by administrator

Log in to admin by Switch User tab and click administrator button in the right-bottom corner of screen. Click UploadData and upload a Seurat object.

4.2 via R session

There are two steps to create a new data via R session. First, create the config file with description of the data and second create the data from a Seurat object.

library(Seurat)
appconf <- createAppConfig(
            title="pbmc_small_test",
            destinationFolder = "pbmc_small_test",
            species = "Homo sapiens",
            doi="10.1038/nbt.3192",
            datatype = "scRNAseq",
            abstract = 'Put the description of the data here.')
createDataSet(
    appconf,
    pbmc_small,
    datafolder=file.path(publish_folder, "data"))

## An object of class Seurat 
## 230 features across 80 samples within 1 assay 
## Active assay: RNA (230 features, 20 variable features)
##  3 layers present: counts, data, scale.data
##  2 dimensional reductions calculated: pca, tsne

dir(file.path(publish_folder, 'data'))

## [1] "pbmc_small"      "pbmc_small_test"

5 Add downloadable file

If you have files intended for user download, kindly save them in the www/download folder. The application will then generate a list, differentiating between files and user folder names, for convenient access to download options. The file named as readme in text format in each folder will be used as descriptions for the files.

6 Distribute to a shiny server

There are two steps to distribute to a shiny server. First, install the package in the server as root user. Second, in a R session run scInit() after load the scRNAseqApp library. If you initialed the app offline, copy the app folder to the shiny server.

Note: the following files need to be writable for shiny: www/database.sqlite, www/counter.tsv and the app www folder should also be writable because the user manager is depend on SQLite, and the SQLite needs to be able to create a journal file in the same directory as the DB, before any modifications can take place. The journal is used to support transaction rollback.

7 SessionInfo

sessionInfo()

## R Under development (unstable) (2024-10-21 r87258)
## Platform: x86_64-pc-linux-gnu
## Running under: Ubuntu 24.04.1 LTS
## 
## Matrix products: default
## BLAS:   /home/biocbuild/bbs-3.21-bioc/R/lib/libRblas.so 
## LAPACK: /usr/lib/x86_64-linux-gnu/lapack/liblapack.so.3.12.0
## 
## locale:
##  [1] LC_CTYPE=en_US.UTF-8       LC_NUMERIC=C              
##  [3] LC_TIME=en_GB              LC_COLLATE=C              
##  [5] LC_MONETARY=en_US.UTF-8    LC_MESSAGES=en_US.UTF-8   
##  [7] LC_PAPER=en_US.UTF-8       LC_NAME=C                 
##  [9] LC_ADDRESS=C               LC_TELEPHONE=C            
## [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C       
## 
## time zone: America/New_York
## tzcode source: system (glibc)
## 
## attached base packages:
## [1] stats     graphics  grDevices utils     datasets  methods   base     
## 
## other attached packages:
## [1] Seurat_5.1.0       SeuratObject_5.0.2 sp_2.1-4           scRNAseqApp_1.7.1 
## [5] BiocStyle_2.35.0  
## 
## loaded via a namespace (and not attached):
##   [1] fs_1.6.5                    matrixStats_1.4.1          
##   [3] spatstat.sparse_3.1-0       bitops_1.0-9               
##   [5] lubridate_1.9.3             httr_1.4.7                 
##   [7] RColorBrewer_1.1-3          doParallel_1.0.17          
##   [9] tools_4.5.0                 sctransform_0.4.1          
##  [11] backports_1.5.0             utf8_1.2.4                 
##  [13] R6_2.5.1                    DT_0.33                    
##  [15] lazyeval_0.2.2              uwot_0.2.2                 
##  [17] rhdf5filters_1.19.0         GetoptLong_1.0.5           
##  [19] withr_3.0.2                 gridExtra_2.3              
##  [21] progressr_0.15.0            cli_3.6.3                  
##  [23] Biobase_2.67.0              spatstat.explore_3.3-3     
##  [25] fastDummies_1.7.4           sass_0.4.9                 
##  [27] spatstat.data_3.1-2         ggridges_0.5.6             
##  [29] pbapply_1.7-2               askpass_1.2.1              
##  [31] slingshot_2.15.0            Rsamtools_2.23.0           
##  [33] R.utils_2.12.3              shinyhelper_0.3.2          
##  [35] parallelly_1.38.0           limma_3.63.0               
##  [37] RSQLite_2.3.7               generics_0.1.3             
##  [39] shape_1.4.6.1               BiocIO_1.17.0              
##  [41] ica_1.0-3                   spatstat.random_3.3-2      
##  [43] dplyr_1.1.4                 Matrix_1.7-1               
##  [45] fansi_1.0.6                 S4Vectors_0.45.0           
##  [47] RefManageR_1.4.0            abind_1.4-8                
##  [49] R.methodsS3_1.8.2           lifecycle_1.0.4            
##  [51] yaml_2.3.10                 SummarizedExperiment_1.37.0
##  [53] rhdf5_2.51.0                SparseArray_1.7.0          
##  [55] Rtsne_0.17                  grid_4.5.0                 
##  [57] blob_1.2.4                  promises_1.3.0             
##  [59] crayon_1.5.3                miniUI_0.1.1.1             
##  [61] lattice_0.22-6              billboarder_0.5.0          
##  [63] cowplot_1.1.3               pillar_1.9.0               
##  [65] knitr_1.48                  ComplexHeatmap_2.23.0      
##  [67] GenomicRanges_1.59.0        rjson_0.2.23               
##  [69] future.apply_1.11.3         codetools_0.2-20           
##  [71] leiden_0.4.3.1              glue_1.8.0                 
##  [73] spatstat.univar_3.0-1       data.table_1.16.2          
##  [75] vctrs_0.6.5                 png_0.1-8                  
##  [77] spam_2.11-0                 gtable_0.3.6               
##  [79] assertthat_0.2.1            cachem_1.1.0               
##  [81] xfun_0.49                   princurve_2.1.6            
##  [83] S4Arrays_1.7.1              mime_0.12                  
##  [85] survival_3.7-0              SingleCellExperiment_1.29.0
##  [87] iterators_1.0.14            statmod_1.5.0              
##  [89] fitdistrplus_1.2-1          ROCR_1.0-11                
##  [91] nlme_3.1-166                bit64_4.5.2                
##  [93] RcppAnnoy_0.0.22            rprojroot_2.0.4            
##  [95] GenomeInfoDb_1.43.0         bslib_0.8.0                
##  [97] irlba_2.3.5.1               KernSmooth_2.23-24         
##  [99] colorspace_2.1-1            BiocGenerics_0.53.1        
## [101] DBI_1.2.3                   tidyselect_1.2.1           
## [103] bit_4.5.0                   compiler_4.5.0             
## [105] curl_5.2.3                  xml2_1.3.6                 
## [107] ggdendro_0.2.0              DelayedArray_0.33.1        
## [109] plotly_4.10.4               scrypt_0.1.6               
## [111] colourpicker_1.3.0          bookdown_0.41              
## [113] rtracklayer_1.67.0          scales_1.3.0               
## [115] lmtest_0.9-40               stringr_1.5.1              
## [117] digest_0.6.37               goftest_1.2-3              
## [119] spatstat.utils_3.1-0        rmarkdown_2.28             
## [121] XVector_0.47.0              htmltools_0.5.8.1          
## [123] pkgconfig_2.0.3             bibtex_0.5.1               
## [125] MatrixGenerics_1.19.0       learnr_0.11.5              
## [127] fastmap_1.2.0               rlang_1.1.4                
## [129] GlobalOptions_0.1.2         htmlwidgets_1.6.4          
## [131] UCSC.utils_1.3.0            shiny_1.9.1                
## [133] farver_2.1.2                jquerylib_0.1.4            
## [135] shinymanager_1.0.410        zoo_1.8-12                 
## [137] jsonlite_1.8.9              BiocParallel_1.41.0        
## [139] R.oo_1.27.0                 RCurl_1.98-1.16            
## [141] magrittr_2.0.3              GenomeInfoDbData_1.2.13    
## [143] dotCall64_1.2               patchwork_1.3.0            
## [145] Rhdf5lib_1.29.0             munsell_0.5.1              
## [147] Rcpp_1.0.13                 TrajectoryUtils_1.15.0     
## [149] reticulate_1.39.0           stringi_1.8.4              
## [151] zlibbioc_1.53.0             MASS_7.3-61                
## [153] plyr_1.8.9                  parallel_4.5.0             
## [155] listenv_0.9.1               ggrepel_0.9.6              
## [157] deldir_2.0-4                Biostrings_2.75.0          
## [159] splines_4.5.0               tensor_1.5                 
## [161] circlize_0.4.16             igraph_2.1.1               
## [163] spatstat.geom_3.3-3         RcppHNSW_0.6.0             
## [165] reshape2_1.4.4              stats4_4.5.0               
## [167] XML_3.99-0.17               evaluate_1.0.1             
## [169] BiocManager_1.30.25         foreach_1.5.2              
## [171] tweenr_2.0.3                httpuv_1.6.15              
## [173] RANN_2.6.2                  tidyr_1.3.1                
## [175] openssl_2.2.2               purrr_1.0.2                
## [177] polyclip_1.10-7             future_1.34.0              
## [179] clue_0.3-65                 scattermore_1.2            
## [181] ggplot2_3.5.1               ggforce_0.4.2              
## [183] xtable_1.8-4                restfulr_0.0.15            
## [185] RSpectra_0.16-2             later_1.3.2                
## [187] viridisLite_0.4.2           tibble_3.2.1               
## [189] memoise_2.0.1               GenomicAlignments_1.43.0   
## [191] IRanges_2.41.0              cluster_2.1.6              
## [193] sortable_0.5.0              timechange_0.3.0           
## [195] globals_0.16.3

References

1.

Franzén, O. & Björkegren, J. L. Alona: A web server for single-cell RNA-seq analysis. Bioinformatics 36, 3910–3912 (2020).

2.

Gardeux, V., David, F. P., Shajkofci, A., Schwalie, P. C. & Deplancke, B. ASAP: A web-based platform for the analysis and interactive visualization of single-cell RNA-seq data. Bioinformatics 33, 3123–3125 (2017).

3.

Pereira, W. J. et al. Asc-seurat: Analytical single-cell seurat-based web application. BMC bioinformatics 22, 1–14 (2021).

4.

Dimitrov, D. & Gu, Q. BingleSeq: A user-friendly r package for bulk and single-cell RNA-seq data analysis. PeerJ 8, e10469 (2020).

5.

Bolisetty, M. T., Stitzel, M. L. & Robson, P. CellView: Interactive exploration of high dimensional single cell RNA-seq data. bioRxiv 123810 (2017).

6.

Li, K. et al. Cellxgene VIP unleashes full power of interactive visualization and integrative analysis of scRNA-seq, spatial transcriptomics, and multiome data. bioRxiv 2020–08 (2022).

7.

Hillje, R., Pelicci, P. G. & Luzi, L. Cerebro: Interactive visualization of scRNA-seq data. Bioinformatics 36, 2311–2313 (2020).

8.

Bernstein, M. N. et al. CHARTS: A web application for characterizing and comparing tumor subpopulations in publicly available single-cell RNA-seq data sets. BMC bioinformatics 22, 1–9 (2021).

9.

Prompsy, P. et al. Interactive analysis of single-cell epigenomic landscapes with ChromSCape. Nature communications 11, 1–9 (2020).

10.

Li, B. et al. Cumulus provides cloud-based data analysis for large-scale single-cell and single-nucleus RNA-seq. Nature methods 17, 793–798 (2020).

11.

Mohanraj, S. et al. Crescent: Cancer single cell expression toolkit. Nucleic Acids Research 48, W372–W379 (2020).

12.

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